Method and apparatus for load switch controller with tracking to support ddr termination

ABSTRACT

A power control device can generate control signals to control operation of power sources. At least one of the control signals may be referenced to an internally provided reference voltage or an externally provided reference voltage. Additional control signals control operation of load switches that can be connected to the power sources to provide secondary sources of power. The load switches can be turned in a gradual manner at rates that depend on the power sources to which they are connected. The outputs of the load switches can be monitored for overvoltage and undervoltage conditions relative to the power sources to which they are connected.

CROSS REFERENCE TO RELATED APPLICATIONS

The present disclosure claims priority to U.S. Provisional App. No. 61/611,414 filed Mar. 15, 2012, the content of which is incorporated herein by reference in its entirety for all purposes.

The present disclosure is related to U.S. application Ser. No. 13/776,274, filed Feb. 25, 2013, the content of which is incorporated herein by reference in its entirety for all purposes.

BACKGROUND

Unless otherwise indicated herein, the approaches described in this section are not prior art to the claims in this application and are not admitted to be prior art by inclusion in this section.

As the complexity and energy efficiency requirements of various types of electronic devices increases due to regulatory requirements and consumer demands, conventional electronic power switches have remained markedly unchanged. For expensive, high-end electronic components that require complex and specific power switching with skew rate control, intricate sequencing and output monitoring, where cost is no object and space restrictions may be a secondary, if not tertiary, concern, various customized systems that utilize expensive and large custom components exist. FIG. 1 shows a block diagram of a conventional notebook computer power architecture.

As shown, such power architectures include a large bill of materials, which more often than not associate with significant cost. Not only is there a need in such power management systems for many low-dropout regulators (LDOs), but also many other disparate power integrated circuits (ICs) such as the CPU regulator, the dual chipset regulator, dual DDR regulator, etc. Because of the complexity and number of power management ICs required, such systems require external microcontrollers or software to control the system using many general-purpose input/out (GPIO) pins and printed circuit board (PCB) traces, all of which contribute to an increased footprint size for the PCB and, ultimately, the device that includes the power managements system.

SUMMARY

A power control device includes controller circuitry for generating primary power control signals to control operation of respective power sources. An internal voltage reference generator provides a programmable reference voltage level for each controller circuit. At least one of the controller circuits may be configured to selective use an externally provided voltage reference in place of the internally provided reference voltage level.

The power control device may further include circuitry for generating secondary power control signals to control operation of respective load switches that are connected to the primary power sources. The slew rate of the load switches may be controlled by the secondary power control signals based on reference voltages stored in the power control device used for operating the primary power sources.

The sequencing of the primary power control signals and the secondary power control signals may be controlled in accordance with configuration data stored in the power control device.

Monitoring circuitry may be provided to monitor the voltage levels of the primary power sources and the load switches. The monitoring circuitry may signal overvoltage and undervoltage conditions. The monitoring circuitry may be used to synchronize the sequencing of the primary power control signals and the secondary power control signals.

The following detailed description and accompanying drawings provide a better understanding of the nature and advantages of the present disclosure.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 illustrates a conventional configuration of power supplies in an electronic circuit.

FIG. 2 illustrates a power supply configuration using a power control device in accordance with the present disclosure.

FIG. 2A illustrates an example GUI that can be used to access configuration data.

FIG. 3 illustrates some detail of a power control device in accordance with a particular embodiment of the present disclosure.

FIGS. 4A and 4B illustrates details of primary power controllers in the power control device of FIG. 3.

FIG. 4C illustrates details of a primary power controller having a selectable reference voltage.

FIG. 5 illustrates an example of power stages controlled by the power control device of FIG. 3.

FIG. 5A illustrates a configuration for DDR operation.

FIG. 6 illustrates an embodiment of secondary power controllers in the power control device of FIG. 3.

FIG. 6A shows details for secondary power controller 304 a.

FIG. 7 illustrates a timing chart for operation of the secondary power controller of FIG. 6A.

FIG. 8 illustrates an embodiment of monitoring circuit for monitoring power controlled by a primary power controller.

FIG. 9 illustrates an embodiment of monitoring circuit for monitoring power controlled by a secondary power controller.

FIG. 10 illustrates an embodiment of monitoring circuit for monitoring power controlled by another primary power controller.

DETAILED DESCRIPTION

In the following description, for purposes of explanation, numerous examples and specific details are set forth in order to provide a thorough understanding of the present disclosure. It will be evident, however, to one skilled in the art that the present disclosure as expressed in the claims may include some or all of the features in these examples alone or in combination with other features described below, and may further include modifications and equivalents of the features and concepts described herein.

FIG. 2 shows a high level block diagram of a power control device 100 in accordance with principles of the present disclosure. The power control device 100 is shown configured in a typical power control application. The power control device 100 may receive an input voltage VIN, which in some embodiments may be 4.5V to 28V. An I²C interface may be provided to allow for programmatic system control and monitoring. FIG. 2A, for example, illustrates an example of a graphical user interface (GUI) that allows a user (e.g., designer) to enter configuration data and other operating data into the power control device 100. The GUI software may communicate with the power control device 100 via the I²C interface to read out data stored in the power control device and to store user-provided data into the power control device.

The power control device 100 may include control input pins and status output pins for system control and monitoring. The power control device 100 may control power sources 202 a, 202 b, 202 c, 202 d for various electronics. For instance, the example shown in FIG. 2 shows components of a computer such as a DDR RAM, an ASIC chipset, and an advance graphics processor (AGP).

In some embodiments, the power control 100 may include one or more DC-DC power controllers 102 a, 102 b, 102 c, 102 d. The DC-DC power controllers 102 a-102 d may generate control signals to control operation of power sources 202 a-202 d such as step-down converters, low drop-out regulators, and so on. In an embodiment, for example, DC-DC power controllers 102 a-102 c may be controllers for buck converters, and DC-DC power controller 102 d may be a controller for a low drop-out (LDO) regulator. Other configurations of DC-DC power controllers may be provided in other embodiments.

In some embodiments, the power control device 100 may include one or more load switch controllers 104 a, 104 b, 104 c, 104 d. The load switch controllers 104 a-104 d may generate control signals to control operation of load switches 204 a, 204 b, 204 c, 204 d that are connected to the power sources 202 a-202 d. Load switches 204 a-204 d may comprise N-channel MOSFET devices, although other load switch designs may be employed.

As can be seen in FIG. 2, the DC-DC power controllers 102 a-102 d may generate control signals to control operation of power sources to produce a programmatically regulated output voltage. In some embodiments, for example, the power source may produce output voltages in the range of 0.5V to 5.0V, but in other embodiments other power sources may designed to produce other voltage levels.

The load switches 204 a-204 d may “tap” off of the voltage outputs of power sources 202 a-202 d to serve as an additional source of power for other devices. In the example shown in FIG. 2, for instance, load switches 204 a and 204 d tap off the voltage output of power source 202 a. Load switch 204 b taps off of power source 202 b, and load switch 204 c taps off power source 202 c. It can be appreciated that, in the general case, a designer may connect any load switch 204 a-204 d to tap power from any power source 202 a-202 d as called for by their particular design. Each power source 202 a-202 d may be configured to output a particular voltage level within a range of voltage levels. In accordance with principles of the present disclosure, the power control device 100 may provide suitable control signals to control operation of any configuration of power sources 202 a-202 d connected to load switches 204 a-204 d, FIG. 2 illustrating an example of one such configuration.

As used herein, the term “primary power source” will refer to the power sources that are controlled by the DC-DC power controllers 102 a-102 d, for example, power sources 202 a-202 d. The DC-DC power controllers 102 a-102 d may therefore be referred to as “primary power controllers”. The term “secondary power source”, likewise, will refer to load switches (e.g., 204 a-204 d), or equivalent devices. The load switch controllers 104 a-104 d may therefore be referred to as “secondary power controllers”.

To explain various aspects of the present disclosure, reference is now made to the illustrative embodiment shown in FIG. 3. The figure shows an internal block diagram of a power control device 300 in accordance with the present disclosure as embodied in the SMB109 digital power control chip, a device that is manufactured and sold by a wholly owned subsidiary of the assignee. The power control device 300 may include primary power controllers 302 a, 302 b, 302 c which generate control signals to control operation of respective primary power sources. In some embodiments, the primary power sources include buck converters. The pin out for each of the primary power controllers 302 a-302 c may include the following:

-   -   BST#—bootstrap input for connection to a bootstrap capacitor     -   DRVH#, DRVL#—respective high side and low side switching outputs     -   SW#—switch node for connection to the high side of the output         inductor     -   CSH#, CSL#—respective high side and low side current sense         inputs     -   FB#—voltage feedback input to a PWM controller     -   COMP#—a frequency compensation input         where “#” is “0” for primary power controller 302 a, “1” for         primary power controller 302 b, and “2” for primary power         controller 302 c.

The power control device 300 may further include a primary power controller 302 d, which generates control signals to control operation of an LDO regulator, which may serve as another kind of primary power source. The pin out for primary power controller 302 d includes LDODRV, which outputs the control signals to a power stage of the LDO regulator, and LDOFB, which is a feedback voltage to an LDO controller portion of the LDO regulator.

The power control device 300 may include secondary power controllers 304 a, 304 b, 304 c, 304 d, producing respective load switch control signals EXTSEQ0, EXTSEQ1, EXTSEQ2, EXTSEQ3 to control operation of respective load switches. The secondary power controllers 304 a-304 d may be included in module 304.

In accordance with principles of the present disclosure, the secondary power controllers 304 a-304 d may provide slew rate control and sequencing control of the load switches controlled by the load switch control signals EXTSEQ0, EXTSEQ1, EXTSEQ2, EXTSEQ3. By controlling the slew rate of the load switches, power from the load switches can be turned ON in a gradual manner rather than in a step fashion, thus reducing the effect of current surge both in the primary power source and in the load driven by the load switch. The sequencing control allows the load switches to be turned on in any desired order, thus providing for controlled power up of electronic systems. The sequencing control may include synchronizing the operations of the primary power controllers 302 a-302 d with operation of the secondary power controllers 304 a-304 d.

A voltage reference block 306 may provide reference voltages Vref0, Vref1, Vref2, Vref3, respectively, for the primary power controllers 302 a-302 d. Thus, for example, Vref0 serves as a reference voltage for primary power controller 302 a, Vref1 serves as a reference voltage for primary power controller 302 b, and so on. The voltage reference block 306 may be programmed to provide a different voltage level, within a range, for each reference voltage Vref0, Vref1, Vref2, Vref3. In a particular embodiment, for example, the voltage reference block 306 may output a voltage level in the range from 0.5V to 2.5V in 9.8 mV steps, for each of Vref0, Vref1, Vref2, and Vref3.

In some embodiments, the power control device 300 may include a VTT configuration block 306 a in order to accept an externally provided V_(TT) reference voltage (e.g., provided via the EN2/VTTFB pin) for double data rate (DDR) memory operation.

System control logic 322 may include control logic (logic gates, firmware, software, etc.) to monitor and control the various operations of the power control device 300. As will be explained below, the system control logic 322 may assert various control signals to coordinate the operations of the power control device 300.

A memory 324 may store various configuration parameters including trimming data for the internal components comprising the power control device 300. The memory 324 may store user provided configuration data that defines the configuration of the primary power controllers 302 a-302 d and the secondary power controllers 304 a-304 d. For example, the memory 324 may store data that sets a voltage level for each reference voltage Vref0, Vref0, Vref2, and Vref3. The memory 324 may include data that associates each secondary power controller 304 a-304 d with a primary power controller 302 a-302 d to which the secondary power controller is connected. For example, referring to FIG. 2 for a moment, the load switches 204 a and 204 c tap power from the power source 202 a. The memory 324 may store data, therefore, to indicate that the load switch controllers 104 a and 104 c are associated with the DC-DC power controller 102 a. Other configuration data that can be stored in the memory 324 may include slew rates information, sequencing information, and the like, which will be described further below.

An oscillator 326 may generate various frequency and timing related clock signals needed by the system control logic 322 to generate timing and control signals. In some embodiments, for example, the oscillator 326 may generate ramp voltages Θ0, Θ1, Θ2, for a current control loop in respective primary power controllers 302 a-302 c.

Referring now to FIG. 4A, additional detail for primary power controller 302 a is described. It will be understood that primary power controllers 302 b and 302 c have similar designs. Primary power controller 302 d is described in FIG. 4B. Continuing with FIG. 4A then, as explained above, in some embodiments, the primary power sources controlled by respective primary power controllers 302 a-302 c may be buck converters. Accordingly, the primary power controller 302 a shown in FIG. 4A constitutes a feedback control stage of a buck converter. FIG. 5 shows an example of a power stage 502 of a buck converter that the primary power controller 302 a may control the operation of The power stage 502 may include a switcher circuit 502 a, 502 b, an inductor 502 c, and an output capacitor 502 d. The switches of the switcher circuit 502 a, 502 b may be N-channel MOSFETs.

The primary power controller 302 a may include a high side driver 402 a that outputs a switcher control signal DRVH0 and a low side driver 402 b that outputs a switcher control signal DRVL0. The “0” designation refers components comprising primary power controller 302 a; Likewise, components of primary power controllers 302 b and 302 c will be designated with “1” and “2”, respectively. The switcher control signals DRVH0, DRVL0 may serve to drive the switcher circuit 502 a, 502 b shown in FIG. 5. A current sense amp 404 senses the inductor current that feeds into a PWM generator 406. A ramp voltage Θ0 from the oscillator 326 feeds into SR flip flop 408. The sensed inductor current together with the ramp voltage Θ0 constitute a current control loop for the primary power controller 302 a.

The output voltage VOUT generated by the power stage 502 feeds back to error amp 410 via pin FB0 and is compared to a reference voltage Vref0 provided by the voltage reference block 306. This creates a control loop that sets the output voltage of the power stage 502 according to the reference voltage Vref0.

As explained above, the voltage reference block 306 may output a voltage level in the range from 0.5V to 2.5V. Referring to FIG. 5, if the voltage divider resistor 504 is omitted from the power stage 502, then the voltage that is fed back to the error amp 410 is VOUT. Accordingly, the primary power controller 302 a will drive the switcher circuit 502 a, 502 b to maintain VOUT=Vref0, thus producing a voltage in the range 0.5V to 2.5V. This configuration may be referred to as “low voltage” mode operation.

On the other hand, if the voltage divider resistor 504 is provided such that a voltage divider ratio of ½ is achieved at FB0, then the voltage that is fed back to the error amp 410 is ½ VOUT. Accordingly, the primary power controller 302 a will drive the switcher to maintain ½ VOUT=Vref0, or VOUT=2×Vref0. To illustrate, for example, VOUT can be controlled to produce a voltage in the range 2.0V to 4.0V by programming Vref0 within the range of 1.0V-2.0V and employing the voltage divider resistor 504 with a ½ voltage divider ratio. This configuration may be referred to as “high voltage” mode operation. The memory 326 may include data that indicates, for each primary power controller 302 a-302 c, whether the primary power controller is configured for low voltage or high voltage operation. In some embodiments, high voltage mode operation may be defined as controlling a primary power source to generate a voltage level for VOUT in the range of 2.5V-5.0V, which can be achieved using a voltage divider resistor 504 that provides a ½ voltage divider ratio and programming the voltage reference block 306 to output a voltage level for Vref# in the range of 1.25V-2.5V.

A deadtime control circuit 412 ensures against ‘shoot through’ across switcher circuit 502 a, 502 b by preventing drivers 402 a and 402 b from turning ON both switcher MOSFETs at the same time.

Referring now to FIG. 4B, the primary power controller 302 d constitutes the LDO controller section of an LDO regulator. The primary power controller 302 d may comprise a combined LDO amplifier and driver 422 to produce a control signal LDODRV. The LDO amplifier 422 receives a reference voltage Vref3 from the voltage reference block 306 to control a power stage comprising pass element 424 to maintain an output voltage level VOUT that is referenced to Vref3. In some embodiments, for example, the pass element 424 may be an N-channel MOSFET.

FIG. 5 illustrates a typical configuration of load switches configured as secondary power sources by tapping power from a primary power source. The figure shows two load switches 512, 514 that are connected to the output VOUT of the power stage 502. In the example shown, the load switches 512, 514 are controlled by respective load switch control signals EXTSEQ2 and EXTSEQ3. When the load switch control signals EXTSEQ2 and EXTSEQ3 turn ON respective load switches 512 and 514, power is tapped from the power stage 502 of the buck converter (primary power source) and provided to loads (not shown) connected to the load switches. The discussion will now turn to a description of the secondary power controllers 304 a-304 d which generate the load switch control signals EXTSEQ0, EXTSEQ1, EXTSEQ2, and EXTSEQ3.

In some embodiments, the power control device 300 may include a primary power controller that can be configured to support double data rate (DDR) memory devices. A supply voltage called VDDQ powers the core, I/O, and logic that comprise a DDR memory. In accordance with current standards for DDR memory devices VDDQ can be set to 2.5V, 1.8V, or 1.5V. The DDR standards call out a reference voltage VTT that provides a threshold between a logic high (“1”) and a logic low (“0”). The reference voltage VTT is typically specified to be in the range from 0.49×VDDQ to 0.51 ×VDDQ, and should adapt to changes in the supply voltage VDDQ.

Accordingly, with reference to FIG. 4C, in a particular embodiment of the power control device 300, the power controller 302 c can be configured for DDR applications. The power control device 302 c may be used to generate the reference voltage VTT, which can then be used by the DDR memory device.

FIG. 4C shows details of the VTT configuration block 306 a illustrated in FIG. 3. In some embodiments, the VTT configuration block 306 a may include two double-throw switches 432, 434 which are controlled by a signal DDROPT. The DDROPT signal may be based on a data value stored in the memory 324. For example, the system control logic 322 may read the memory 324 and assert DDROPT according to the data that is read out of the memory. In some embodiments, the DDROPT signal may be set in real time from the I²C communication interface via the SDA pin (FIG. 3).

The switch 432 selects between the Vref2 output of the voltage reference block 306 and an externally provided voltage level via input pin ENV2/VTTFB. The output of switch 432 (Vref2A) feeds into the error amplifier 410 comprising the power controller 302 c. The switch 434 selects between the externally provided voltage level via input pin ENV2/VTTFB and ground potential (via a grounding resistor R).

If the power controller 302 c is not configured for use with a DDR memory device, then the DDROPT signal may be de-asserted (e.g., logic LO). Accordingly, switches 432, 434 may be operated to their “0” position. The programmable Vref2 output of the voltage reference block 306 will feed into the error amplifier 410, via switch 432. An internal signal EN2A will be connected to the ENV2/VTTFB pin, via switch 434, which may be tied to an externally provided logic HI. The signal EN2A may be used by circuitry (e.g., system control logic 322) to know that the power controller 302 c is operating from the internally generated Vref2. For example, in some embodiments, the system control logic 322 may perform a conventional “soft start” sequence for turning on the buck converter, whereby the reference voltage Vref2 is gradually ramped up from 0V to its final value.

If the power controller 302 c is configured for use with a DDR memory device, then the DDROPT signal may be asserted (e.g., logic HI), for example, as described above. Switches 432, 434 may be operated to their “1” position by the DDROPT signal. The ENV2/VTTFB pin will be connected to an externally provided reference voltage that is in the range of 0.49×VDDQ to 0.51×VDDQ. This externally provided reference voltage will feed into the error amplifier 410 via switch 432, thus providing the correct reference voltage for generating VTT.

In some embodiments, the power controllers 302 a-302 c may operate their respective power stages in one of two commonly known modes of operation: continuous conduction mode or discontinuous conduction mode (may be referred to as “pulse skipping” mode). However, when the power controller 302 c is configured for DDR mode, the power controller should operated to produce VTT in continuous conduction mode. Accordingly, in some embodiments, the EN2A signal may be connected to logic LO via the switch 434 when the DDROPT signal is asserted. The system control logic 322 may respond to the to the EN2A signal being asserted LO by restricting the power controller 302 c to operate only in continuous conduction mode.

FIG. 5A illustrates a typical DDR mode configuration, using a power controller (e.g., 302 b) to produce VDDQ, and feeding a reference voltage based on VDDQ to power controller 302 c to produce VTT. The power stage 522 provides VDDQ. The voltage level for VDDQ may be set to 2.5V, 1.8V, or 1.5V by programming the voltage reference block 306 to generate an appropriate level for Vref1. A voltage divider network 524 provides a divide-by-two output of VDDQ (½×VDDQ) that can be connected to the ENV2/VTTFB pin. The power stage 542 may be controlled by the power controller 302 c to provide VTT referenced to ½×VDDQ that is produced from the power stage 302 b.

Referring to FIG. 6, the module 304 may comprise a slew rate unit 602, which provides two output levels: a 1× output and a 2× output. Each output of the slew rate unit 602 feeds into control units 604 a, 604 b, 604 c, 604 d, which generate respective load switch control signals EXTSEQ0, EXTSEQ1, EXTSEQ2, EXTSEQ3. Each secondary power controller 304 a-304 d therefore may comprise the slew rate unit 602 operating in combination with respective control units 604 a-604 d.

The slew rate unit 602 receives various signals from the system control logic 322. For example, a clock signal CLKSRC# provides a time base for the slew rate unit 602. The system control logic 322 may assert a separate clock signal CLKSRC# for each secondary power controller 304 a-304 d is active. The system control logic 322 also asserts an enable signal SRCEN0, SRCEN1, SRCEN2, SRCEN3 corresponding to the secondary power controllers 304 a-304 d that is active.

A mode selector 606 selects a mode indicator HVO0, HVO1, HVO2 corresponding to each primary power controller 302 a-302 c. The mode indicator indicates whether the corresponding primary power controller 302 a-302 d is operating in high voltage mode (e.g., outputs 2.5V-5.0V) or low voltage mode (e.g., outputs 0.5V-2.5V). The system control logic 322 asserts bits ICHIO0 and ICHIO1 to identify one of the primary power controllers 302 a-302 c. For example, ‘00’b may be associated with primary power controller 302 a and thus select HVO0, ‘01’b may be associated with primary power controller 302 b and thus select HVO1, and ‘10’b may be associated with primary power controller 302 c and thus select HVO2. In some embodiments, the mode selector 606 may be a multiplexer (e.g., a 4:1 mux) that outputs one of the mode indicators HVO0, HVO1, or HVO2 to each of the control units 604 a-604 d, depending on which secondary power controllers 304 a-304 d is/are active and which primary power controller 302 a-302 c is associated with the active secondary power controller(s).

The control units 604 a-604 d each have corresponding enable signals (e.g., ENA_SRC0) and disable signals (e.g., EOSRC0), which the system control logic 322 may assert to coordinate with operation of the slew rate unit 602.

FIG. 6A shows details of the slew rate unit 602 and control unit 604 a, which together operate as secondary power controller 304 a. Control units 604 b-604 d are similarly constructed. Secondary power controller 304 b comprises the combination of slew rate unit 602 and control unit 604 b, secondary power controller 304 c comprises the combination of slew rate unit 602 and control unit 604 c, and so on.

The slew rate unit 602 includes a one-shot to generate pulses at a rate set by the incoming clock signal CLKSRC0. The one-shot operates a non-overlapping (NOL) switch to charge capacitor C_(src) at a rate set by the clock signal CLKSRC0. A grounding switch connected across capacitor C_(src) maintains the capacitor in a discharged state until the system control logic 322 asserts the enable signal SRCEN0. The capacitor voltage V_(CSRC) feeds into a buffer 612. The buffer 612 may comprise an op-amp configured as a non-inverting amplifier with a gain factor of two. The output of the buffer 612 may be referred to as the “2×output” to reflect the 2×gain of the op-amp. Another output, called the “1×output”, is taken from the resistor divider feedback network and has unity gain.

The control unit 604 a includes an output driver 622 that outputs the load switch control signal EXTSEQ0, which in some embodiments may be a MOSFET device. The output driver 622 may be turned ON by closing any of three switches 624, 626, and 628. Switch 624 will connect the 1×output of buffer 612 to the gate of the output driver 622. Switch 626 will connect the 2×output of buffer 612 to the gate of output driver 622. Switch 628 will connect VDDH to the gate of output drive 622, which in some embodiments may be 10V. The signals ENA_SRC0 and EOSRC0, along with mode indicator HVO0, HVO1, or HVO2 from the mode selector 606, control the closing and opening of the switches 624-628 in accordance with the logic 632.

Operation of the secondary power controller 304 a shown in FIG. 6A will now be explained in connection with the timing chart of FIG. 7. Generally, in accordance with principles of the present disclosure, the slew rate unit 604 generates a load switch control signal EXTSEQ0 that can control the slew rate of the load switch 610. This allows the load switch 610 to be turned ON in a gradual manner to a final output voltage level determined by the primary power source to which the load switch is connected. After the load switch 610 has reached its final output voltage level, the secondary power controller 304 a can maintain the load switch in the ON state until it is time to be turned OFF (e.g., during a power down operation).

Referring to FIG. 7, when the system control logic 322 is ready to enable secondary power controller 302 a, it will assert a clock signal CLKSRC0, which will set the slew rate of the load switch 610. For example, the memory 324 may store data that represent slew rates for each secondary power controller 304 a-304 d. The data may be used by the system control logic 322 to generate a suitable clock signal CLKSRC#.

Asserting the clock signal CLKSRC0 will start the one-shot running. However, until the system control logic 322 asserts SRCEN0, the capacitor C_(src) will not charge up. The system control logic 322 may set the ICHIO0 and ICHIO1 bits on the mode selector 606 according to the primary power controller 302 a-302 c that is associated with the secondary power controller 304 a. The high voltage mode indicator HVO# of the associated primary power controller will feed through the mode selector 606 to the logic 632.

At time point A in FIG. 7, the system control logic 322 may assert ENA_SRC0 and SRCEN0 (EOSRC0 is de-asserted at this time). Depending on the high voltage mode indicator HVO#, the output driver 622 will be connected to either the 1×output via switch 624 or the 2×output via switch 626. For example, if the HVO# indicator indicates high voltage operation, then the output driver 622 will be connected to the 2×output. This aspect of the present disclosure will be discussed in more detail below.

As the one-shot charges capacitor C_(src), the capacitor voltage V_(CSRC) increases in a staircase fashion and starts driving the output driver 622; there may be a latency period due to open loop control. The load switch control signal EXTSEQ0 will gradually increase, thus providing slew rate control of the load switch 610 and gradually turning ON the load switch. As can be seen in FIG. 7, the voltage output V_(LSW0) of the load switch 610 begins to ramp up (slew) in concert with the staircase increase of V_(CSRC).

In a particular embodiment of the present disclosure, the system control logic 322 counts 357 tics of the clock signal CLKSRC0 and ramps V_(CSRC) from 0V-3.5V in that period of time. This can be achieved by properly designing the pulse width of the one-shot T_(ON). It will be appreciated, of course, that these design parameters are specific to a particular embodiment of the present disclosure and that other values may be used. At time point B in FIG. 7, when the last tic has been counted, the system control logic 322 asserts signal EOSRC0 to designate the end of slew rate control. When EOSRC0 is asserted, the logic 632 will cause the switches 624 and 626 to be open, and close switch 628. Switch 628 pulls the driver 622 to VDDH, which is a voltage level sufficient to fully turn ON the output driver 622 (e.g., 10V), which in turn, fully turns ON the load switch 610.

When at time point C, it is time to turn OFF the load switch 610, the system control logic 322 may de-assert ENA_SRC0. This will open switch 628 and thus turn OFF output driver 622.

Operation of the slew rate unit 602 during low voltage mode and during high voltage mode operation will now be described. Recall that the primary power controllers 302 a-302 c may operate in a low voltage mode in the range 0.5V-2.5V. Accordingly with reference to FIG. 6A, in low voltage mode, the drain of load switch 610 will be connected at most to VOUT=2.5V, the highest output voltage of the primary power source to which the load switch is connected in low voltage mode. As explained above, the system control logic 322 operates the slew rate unit 602 to ramp V_(CSRC) from 0V-3.5V. As explained above, in low voltage mode operation, the output driver 622 is driven by the 1×output of buffer 612, which will vary from 0V-3.5V. Likewise, the load switch 610 will be driven by EXTSEQ0 to about 3.5V, taking into account the voltage thresholds V_(th) of the output driver 622 and the load switch. By ramping EXTSEQ0 to about 3.5V, the slew rate unit 604 can ensure that the load switch 610 will be slewed to whatever output voltage the primary power source produces in low voltage mode by the time (e.g., time point B in FIG. 7) the system control logic asserts signal EOSRC0.

Referring to FIG. 7, for instance, the timing chart illustrates an example where the load switch 610 is connected to a primary power source that is configured to output a voltage level of 1.2V (i.e., low voltage mode). At time point D, the output voltage of the load switch 610 has slewed to 1.2V, before time point B when the output driver 622 is pulled up to VDDH by switch 628.

If, on the other hand, the primary power source to which the load switch 610 is connected is configured for high voltage mode operation, then the output voltage of the primary power source may be operated in the range of 2.5V-5.0V. As explained above, the output driver 622 will be driven by the 2×output of buffer 612 in high voltage mode because the mode indicator will indicate high voltage mode operation. The output voltage of the 2×output will range from 0.0V-7.0V. Accordingly, the load switch control signal EXTSEQ0 will ramp to about 7.0V, which ensures that the load switch 610 will be slewed to whatever output voltage the primary power source produces in high voltage mode by the time (e.g., time point B in FIG. 7) the system control logic asserts signal EOSRC0.

An aspect of the present disclosure is sequence control. In accordance with the present disclosure, the system control logic 322 may control the sequencing of the primary power controllers 302 a-302 d and the secondary power controllers 304 a-304 d, more conveniently referred to here collectively as “channels”. The memory 324 may store data that can be used by the system control logic 322 to indicate the order in which to enable the channels. Generally, the channels may be enabled in any order that is suitable for a given design. In addition, one or more channels may be enabled at the same time. It will be appreciated of course that a secondary power controller should only be enabled after its associated primary power controller has been enabled previously, to ensure that the load switch controlled by that secondary power controller has power to output when the load switch is turned ON.

The following represents illustrative examples of channel activation sequences, where Pi represents the i^(th) primary power controller and can be any one of primary power controllers 302 a-302 d. Similarly, Si represents the i^(th) secondary power controller in each sequence and can be any one of secondary power controllers 304 a-304 d.

-   -   P1, P2, P3, P4, S1, S2, S3, S4—Here, the primary power         controllers are enabled in sequence first, then the secondary         power controllers are enabled in sequence.     -   P1, S1, P2, [S2, S3], P3, S4, P4—Here, primary power controller         P1 is enabled first, followed by a secondary power controller         51, followed by another primary power controller P2, and so on.         The bracket notation indicates that secondary power controllers         S2 and S3 are enabled at the same time. This sequence example         may be appropriate if S1 uses power from P1, S2 and S3 use power         from P2, and S4 uses power from P3. Note that P4 is not         associated with any secondary power controller.     -   P1, [S1, S2], P2, S3—This sequence illustrates that not all of         the power controllers need to be enabled, showing the activation         of only two of the primary power controllers and three of the         secondary power controllers. For example, the design may only         use two primary power sources and three secondary power sources.

An aspect of the present disclosure is synchronized operation. In accordance with the present disclosure, the system control logic 322 may synchronize the activation of a sequence of channels, in order to control when to enable subsequent channels in the sequence. The system control logic 322 may be programmed (e.g., using configuration data stored in memory 324) to use any of a number of synchronization triggers. In some embodiments, the trigger may be a time delay. For example, the system control logic 322 may be programmed to delay for some period of time after activating one channel before activating the next channel in the sequence.

In other embodiments, the system control logic 322 may use one or more pins on the power control device 300 to receive externally generated signals as the trigger. As will be described below, voltage monitoring circuitry may be provided to detect overvoltage and undervoltage conditions. During startup, the system logic 322 may use undervoltage signals as the triggers for deciding when to enable the next channel in the sequence. For example, the system control logic 322 may enable a subsequent channel the undervoltage condition for the current channel is de-asserted, or after a period of time has elapsed.

In still other embodiments, the trigger may be a communication on the I²C bus (SDA pin, FIG. 3). For example, logic external to the power control device 300 may communicate a triggering message to the system control logic 322 over the I²C bus.

An aspect of the present disclosure is overvoltage and undervoltage detection. In some embodiments, the power control device 300 may provide monitoring for overvoltage and undervoltage conditions on each of the primary power sources and second power sources controlled by respective primary power controllers 302 a-302 d and secondary power controllers 304 a-340 d. The power control device 300 may include monitoring circuits to monitor for overvoltage and undervoltage conditions. When any either condition occurs, a PGOOD pin (FIG. 3) may be de-asserted. The PGOOD pin may be used by logic outside of the power control device 300 to determine that an overvoltage or undervoltage condition has occurred.

FIG. 8 illustrates an embodiment of monitoring circuitry 800 that can be used with the primary power controllers 302 a-302 d. In some embodiments, an instance of monitoring circuitry 800 is provided for each primary power controller 302 a-302 d. The figure shows the monitoring circuitry 800 for primary power controller 302 b, as indicated by the “1” designation in the signal line labels. Similar monitoring circuitry is provided for each of the other primary power controllers.

The input pin CSL1 is connected to the output VOUT of the primary power source (e.g., power stage of buck converter, see FIG. 5) that is controlled by primary power controller 302 b. A comparator section 802 compares VOUT against the reference voltage Vref1 (from voltage reference block 306) that is associated with primary power controller 302 b.

The output voltage range of the voltage reference block 306 is 0.5V-2.5V. Therefore, Vref1 will be some value between 0.5V and 2.5V. Recall that each primary power source may be operated in high voltage mode (e.g., 2.5V-5.0V) or in low voltage mode (e.g., 0.5V-2.5V). Accordingly, in accordance with the present disclosure, a switch 804 will feed CSL1 or ½×CSL1 (via the voltage divider 806) to the comparator section 802, depending on whether the primary power source is operating in high voltage mode or low voltage mode as determined by the mode indicator HVO1.

The comparator section 802 may comprise an overvoltage (OV) comparator and an undervoltage (UV) comparator. The OV and UV comparators receive Vref1 from the voltage reference block 306 on their respective non-inverting and inverting inputs. V_(THOV1) is a programmable threshold value for overvoltage determination. V_(THUV1) is a programmable threshold value for undervoltage determination. In some embodiments, the memory 324 may store threshold data that can be used to determine V_(THOV1) and V_(THUV1). For example, the memory 324 may store percentage values so that V_(THOV1) is determined as a percentage of Vref1 and V_(THUV1) is determined as a percentage of Vref1.

The OV comparator compares Vref1 with the quantity (VOUT−V_(THOV1)) or the quantity (½VOUT−V_(THOV1)), depending on the mode indicator HVO1, and asserts signal OV_CH1 if Vref1 is less than the compared quantity to indicate an overvoltage condition. The UV comparator compares Vref1 with the quantity (VOUT+V_(THUV1)) or the quantity (½VOUT+V_(THUV1)), depending on the mode indicator HVO1, and asserts signal UV_CH1 if Vref1 is greater than the compared quantity to indicate an undervoltage condition.

The time delays of 200 nS and 400 nS provide a signal delay in case of noisy environments, where there may be small voltage fluctuations. For similar reasons, the OV and UV comparators may include hysteresis (e.g., 25 mV) to allow for small voltage fluctuations that could cause OV_CH1 and UV_CH1 to flutter.

Operation of the OV reset comparator and OV 25 mV comparator do not rely on Vref1 or the mode indicator HVO1 and thus will not be discussed.

The monitoring circuitry shown in FIG. 8 is for monitoring the output voltage of a power stage controlled by power controller 302 b. A similar circuit is provided for power controller 302 c, and operation is the same. Recall from FIG. 4C, however, that the voltage reference Vref2 may be the output of the voltage reference block 306 or may be an externally provided level, depending on whether DDR mode is in effect. Accordingly, the comparator section 802 of the monitoring circuitry for power controller 302 c will automatically receive the correct reference voltage Vref2 for detecting an overvoltage or undervoltage condition.

FIG. 9 illustrates an embodiment of monitoring circuitry 900 that can be used with the secondary power controllers 304 a-304 d. In some embodiments, an instance of monitoring circuitry 900 is provided for each secondary power controller 304 a-304 d. The figure shows the monitoring circuitry 900 for secondary power controller 304 a, as indicated by the “0” designation in the signal line labels. Similar monitoring circuitry is provided for each of the other secondary power controllers.

The input pin SEQFB0 is connected to the output VOUT of the secondary power source that is controlled by secondary power controller 304 b; e.g., load switch 910. A comparator section 902 compares VOUT against a reference voltage (from voltage reference block 306) that is associated with secondary power controller 304 a. The reference voltage is based on the output voltage of the power source controlled by the primary power controller that is associated with the secondary power controller 304 a.

A switch 904 will feed SEQFB0 or ½×SEQFB0 (via the voltage divider 906) to the comparator section 902. The primary power source that is associated with the secondary power controller 304 a may be operated in high voltage mode (e.g., 2.5V-5.0V) or in low voltage mode (e.g., 0.5V-2.5V). As explained above, however, the output voltage range of each voltage (Vref[0-2]) in the voltage reference block 306 is 0.5V-2.5V. Accordingly, if the associated primary power source is operating in high voltage mode, then switch 904 is operated by the mode indicator HVO# that corresponds to that primary power source to feed ½×SEQFB0 to the comparator section 904.

Since the secondary power controller 304 a can be associated with any one of primary power controllers 302 a-302 c, a voltage reference selector 908 a may be provided to select the reference voltage corresponding to the primary power controller that the secondary power controller is associated with. A mode selector 908 b may be provided to select the corresponding mode indicator of the associated primary power controller.

Recall from FIG. 4C, that power controller 302 c may be operated in DDR mode, in which case the reference voltage Vref2 is an externally provided voltage level instead of coming from the voltage reference block 306. This is reflected in FIG. 9 by the label “V_(REF2A)”, indicating that the voltage reference selector 908 a may receive Vref2 from the voltage reference block 306 in non-DDR mode, or from an externally provided source in DDR mode.

V_(THOVLSW0) is a programmable threshold value for overvoltage determination. V_(THUVLSW0) is a programmable threshold value for undervoltage determination. In some embodiments, the memory 324 may store threshold parameters that can be used to determine V_(THOVLSW0) and V_(THUVLSW0). For example, the memory 324 may store percentage values so that V_(THOVLSW0) is determined as a percentage of the reference voltage selected by the voltage reference selector 908 a and V_(THUVLSW0) is determined as a percentage of the selected reference voltage.

The operation of the OV comparator and the UV comparator in FIG. 9 are the same as described in FIG. 8.

FIG. 10 illustrates an embodiment of monitoring circuitry 1000 that can be used with the primary power controller 302 d (namely, the low dropout controller). The input pin LDOFB is connected to the output VOUT of the power stage 1010 that is controlled by primary power controller 302 d. A comparator section 1002 compares VOUT against the reference voltage Vref3 from voltage reference block 306. The operation of the OV comparator and the UV comparator in FIG. 10 are the same as described in FIG. 8.

The above description illustrates various embodiments of the present disclosure along with examples of how aspects of the particular embodiments may be implemented. The above examples should not be deemed to be the only embodiments, and are presented to illustrate the flexibility and advantages of the particular embodiments as defined by the following claims. Based on the above disclosure and the following claims, other arrangements, embodiments, implementations and equivalents may be employed without departing from the scope of the present disclosure as defined by the claims. 

We claim the following:
 1. A circuit comprising: a voltage reference generator having a plurality of voltage reference outputs, each voltage reference output having a selectable voltage level; a plurality of primary power controllers, each primary power controller connected to receive a voltage reference level from one of the voltage reference outputs of the voltage reference generator, each primary power controller operative to generate switcher control signals that can control operation of a power stage to produce an output voltage that is referenced to the voltage reference level; and a selector circuit having a first input connected to receive a first voltage reference output from the voltage reference generator, a second input for connection to an externally provided voltage level, and a voltage reference output connected to a first primary power controller, wherein the first primary power controller can be selectively referenced to the first voltage reference output or the externally provided voltage level.
 2. The circuit of claim 1 further comprising a memory, wherein the selector circuit further comprises a selector input that can receive data from the memory.
 3. The circuit of claim 1 further comprising a communication port, wherein the selector circuit further comprises a selector input that can receive data from the communication port.
 4. The circuit of claim 1 further comprising a plurality of secondary power controllers, each secondary power controller being associated with one of the primary power controllers, each secondary power controller operative to generate a load switch control signal that can control a load switch to produce, at a selectable slew rate, an output voltage that is referenced to the voltage reference level of the primary power controller that is associated with said each secondary power controller.
 5. The circuit of claim 4 further comprising a slew rate controller operative to produce a slew signal, each second power controller comprising a driver that is selectively connected to and controlled by the slew signal to produce the load switch control signal.
 6. The circuit of claim 5 wherein the driver is further selectively controlled by a constant voltage potential to produce the load switch control signal.
 7. The circuit of claim 5 further comprising a clock signal that controls an operating frequency of the slew rate controller, the clock signal being selectable depending on the second power controller that is connected the slew rate controller.
 8. The circuit of claim 4 further comprising a memory having stored therein association data that sets forth an association between each secondary power controller and one of the primary power controllers.
 9. The circuit of claim 4 further comprising control logic operative to produce control signals to enable the secondary power controllers, in accordance with a selectable order, to generate load switch control signals.
 10. The circuit of claim 9 wherein the control logic is further operative to produce a clock signal that controls the slew rate associated with an enabled secondary power controller.
 11. The circuit of claim 4 wherein a load switch that is controlled by one of the secondary power controllers is connected to a power stage that is controlled by the primary power controller associated with said one of the secondary power controllers.
 12. An integrated circuit device comprising: first circuit means for generating a plurality of primary power control signals to control operation of a plurality of respective power sources; second circuit means for generating a plurality of load switch control signals to control operation of a plurality of respective load switches connected to the power sources; third circuit means for generating a slew rate control signal, the second circuit means including connection means for selectively connecting to an output of the third circuit means to generate a load switch control signal using the slew rate control signal; fourth circuit means for storing: a mode indicator associated with each power source that indicates whether the first circuit means is operating said each power source in a high voltage mode or in a low voltage mode; and association information indicating an association between power sources and load switches; and fifth circuit means for selecting between an internally generated reference voltage level or an externally provided voltage level, wherein a first primary power control signal is generated based on a voltage level selected by the firth circuit means.
 13. The integrated circuit of claim 12 wherein the fifth circuit means selects between the internally generated reference voltage level and the externally provided voltage level based on data stored in the fourth circuit means.
 14. The integrated circuit of claim 12 further comprising a communication port, wherein the fifth circuit means selects between the internally generated reference voltage level and the externally provided voltage level based on data received from the communication port.
 15. The integrated circuit of claim 12 wherein the third circuit means generates a slew rate control signal for a first load switch to slew an output of the first load switch at a rate that is determined based on the mode indicator of the power source associated with the first load switch.
 16. The integrated circuit of claim 12 wherein the first circuit means comprises a plurality of primary power controller circuits, each primary power controller circuit generating corresponding primary power control signals.
 17. The integrated circuit of claim 12 wherein the second circuit means comprises a plurality of control circuits, each control circuit generating a corresponding load switch control signal.
 18. The integrated circuit of claim 12 further comprising a voltage reference generator to generate reference voltages used by the first circuit means to control the power sources to produce output voltages according to the reference voltages.
 19. The integrated circuit of claim 18 further comprising monitoring circuitry to monitor voltage levels of the load switches controlled by the second circuit means to detect undervoltage and overvoltage conditions based on the reference voltages from the voltage reference generator to which the load switches are connected.
 20. The integrated circuit of claim 12 wherein the fourth circuit means stores a slew rate parameter corresponding to each load switch, wherein the third circuit means generates a first slew rate control signal using the slew rate parameter corresponding to the load switch that is controlled by the first slew rate control signal.
 21. A method in a circuit comprising: storing configuration data in the circuit indicative of a plurality of reference voltage levels associated with a plurality of power sources; generating within the circuit a plurality of primary control signals to operate the power sources according to their corresponding reference voltage levels to output corresponding voltage levels; and generating within the circuit a plurality of secondary control signals to operate load switches connected to the primary power sources, wherein the secondary control signals control a slew rate of each load switch according to the reference voltage level stored in the circuit that corresponds to the primary power source to which said each load circuit is connected, wherein generating a first primary control signal includes selecting between an internally generated reference voltage level and an externally provided voltage level to generate the first primary control signal.
 22. The method of claim 21 further comprising controlling power sources that are connected to the circuit using the primary control signals and controlling load switches that are connected to the circuit using the secondary control signals.
 23. The method of claim 21 further comprising storing configuration data in the circuit indicative of a sequence by which the primary control signals and the secondary control signals are generated.
 24. The method of claim 21 further comprising monitoring an output voltage levels of the load switches and using the reference voltage levels stored in the circuit to trigger an undervoltage signal or an overvoltage signal based on comparisons of the output voltage levels of the load switches and the stored reference voltage levels. 